Models of waveguides combining gradient and nonlinear optical layers

Сергей Савотченко, S. Savotchenko
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Abstract

Objectives. Theoretical studies of the waveguide properties of interfaces between nonlinear optical and graded-index media are important for application in optoelectronics. Waveguides combining layers with different optical properties seem to be the most promising, since they can be matched to optimal characteristics using a wide range of control parameters. The paper aims to develop a theory of composite optically nonlinear gradedindex waveguides with an arbitrary profile, within which it is possible to obtain exact analytical expressions for surface waves and waveguide modes in an explicit form. The main feature of the theory proposed in this paper is its applicability for describing surface waves and waveguide modes, in which the field is concentrated inside the gradient layer and does not exceed its boundary, avoiding contact with the nonlinear layer.Methods. Analytical methods of the theory of optical waveguides and nonlinear optics are used.Results. A theoretical description of the waveguide properties of the interface between two media having significantly different optical characteristics is carried out. The formulated model of a plane waveguide is applicable to media having an arbitrary spatial permittivity profile. An analytical expression describing a surface wave propagating along the interface between a medium having stepwise nonlinearity and a gradient layer with an arbitrary permittivity profile is obtained. Additionally, analytical expressions for surface waves propagating along the interface between a medium with Kerr nonlinearity (both self-focusing and defocusing), as well as graded-index media characterized by exponential and linear permittivity profiles, are obtained.Conclusions. The proposed theory supports a visual description in an explicit analytical form of a narrowly localized light beam within such waveguides. It is shown that by combining different semiconductor crystals in a composite waveguide, it is possible to obtain a nonlinear optical layer on one side of the waveguide interface and a layer with a graded-index dielectric permittivity profile on the other.
结合梯度和非线性光学层的波导模型
目标。非线性光学介质与梯度折射率介质界面波导特性的理论研究对于光电子学的应用具有重要意义。结合具有不同光学特性的层的波导似乎是最有前途的,因为它们可以使用广泛的控制参数来匹配最佳特性。本文的目的是建立一个具有任意轮廓的复合光学非线性梯度波导理论,在该理论中,表面波和波导模式可以用显式形式得到精确的解析表达式。本文提出的理论的主要特点是它适用于描述表面波和波导模式,其中场集中在梯度层内,不超过其边界,避免与非线性层接触。采用了光波导理论和非线性光学的分析方法。对两种具有明显不同光学特性的介质之间的界面的波导特性进行了理论描述。所建立的平面波导模型适用于具有任意空间介电常数分布的介质。得到了表面波沿具有逐步非线性的介质和具有任意介电常数剖面的梯度层之间的界面传播的解析表达式。此外,还得到了表面波沿具有克尔非线性(自聚焦和散焦)介质和以指数和线性介电常数分布为特征的分级折射率介质之间的界面传播的解析表达式。提出的理论支持以明确的分析形式对这种波导内狭窄的局部光束进行视觉描述。结果表明,通过在复合波导中组合不同的半导体晶体,可以在波导界面的一侧获得非线性光学层,在另一侧获得具有梯度折射率介电常数分布的层。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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